TF-IUPS160024 174..178


ORIGINAL ARTICLE

Associations between urinary kidney injury biomarkers and cardiovascular
mortality risk in elderly men with diabetes

Aleksandra Tonkonogia, Axel C. Carlssona,b, Johanna Helmersson-Karlqvistc, Anders Larssonc and Johan €Arnl€ova,d

aDepartment of Medical Sciences, Cardiovascular Epidemiology, Uppsala University, Uppsala, Sweden; bDivision of Family Medicine,
Department of Neurobiology, Care Sciences and Society, Karolinska Institutet, Huddinge, Sweden; cDepartment of Medical Sciences,
Biochemical Structure and Function, Uppsala University, Uppsala, Sweden; dSchool of Health and Social Studies, Dalarna University, Falun,
Sweden

ABSTRACT
Aim: Three urinary biomarkers, kidney injury molecule-1 (KIM-1), neutrophil gelatinase-associated lipoca-
lin (NGAL), and cystatin C, have been suggested as clinically relevant highly specific biomarkers of acute
kidney tubular damage. Yet, the utility of these biomarkers in the prognostication of diabetic nephrop-
athy has been less studied. Therefore, we aimed to investigate the longitudinal association between
these urinary biomarkers and cardiovascular mortality in patients with diabetes.
Methods: The study sample consisted of participants with diabetes in the community-based Uppsala
Longitudinal Study of Adult Men (n¼91; mean age 77.8 years). During follow-up (median 8.3 years,
interval 0.7–13.4 years), 33 participants died of cardiovascular causes.
Results: In a multivariable Cox regression model adjusting for age, glomerular filtration rate, and urinary
albumin/creatinine ratio, higher urinary KIM-1/creatinine was associated with an increased risk for car-
diovascular mortality (HR per SD increase 1.51, 95% confidence intervals 1.03–2.24, P¼0.03). Neither
urinary NGAL/creatinine nor urinary cystatin C/creatinine were independently associated with an
increased cardiovascular mortality risk.
Conclusion: In elderly men with diabetes, higher urinary KIM-1/creatinine was associated with an
increased long-term risk of cardiovascular mortality independently of established markers of diabetic
nephropathy. Our data provide support for kidney tubular damage as an important aspect of diabetic
nephropathy that merits further investigation.

ARTICLE HISTORY
Received 10 January 2016
Revised 15 May 2016
Accepted 16 May 2016

KEY WORDS
Biomarkers; diabetes;
epidemiology; kidney; KIM-1

Introduction

The prevalence of diabetes mellitus and diabetic nephropathy
is escalating globally (1). The underlying pathology leading to
diabetic nephropathy is multifactorial, and tubular damage
appears early in disease development and may precede
glomerular damage (2). Yet, to date, the role of kidney tubu-
lar damage in diabetic nephropathy is incompletely under-
stood. The currently used established kidney disease
biomarkers for diagnosing diabetic nephropathy, urinary albu-
min/creatinine ratio and creatinine-based estimated glomeru-
lar filtration rate, have limited sensitivity and specificity as
they are influenced by many extra-renal factors.

Therefore, further exploration of specific tubular damage
biomarkers in diabetic nephropathy may prove to be clinically
important. Urinary kidney injury molecule-1 (uKIM-1) (3,4),
neutrophil gelatinase-associated lipocalin (uNGAL) (5,6), and
cystatin C (uCystC) (7,8) have all been suggested as highly
specific biomarkers for acute tubular damage; however, the
aforementioned biomarkers may also indicate chronic tubular
damage. Yet, data on long-term prognostic importance of
these biomarkers in patients with diabetes are limited.

KIM-1 is a transmembrane protein, almost exclusively
expressed on the apical surface of proximal tubule cells as a

response to injury, and its expression does not disappear until
the damage is totally resolved (3). NGAL is a protein which is
a part of the lipocalin superfamily (5), expressed in the thick
ascending limb of Henle’s loop and collecting ducts as a
response to injury.

Cystatin C is freely filtered through glomeruli (9) and there-
after reabsorbed and degraded in the proximal tubuli. Thus,
only trace amounts can be found in the urine from healthy
kidneys (10).

In the present study, we hypothesized that chronic kidney
tubular damage may increase the risk of macrovascular com-
plications in patients with diabetes. Accordingly, we aimed to
investigate the association between three kidney tubular
damage biomarkers and the risk for cardiovascular mortality
in a study population of elderly men with diabetes.

Material and methods

The Uppsala Longitudinal Study of Adult Men (ULSAM) was
used as study samples. The design has been described previ-
ously (http://ww.pubcare.uu.se/ULSAM) (11–13). The analyses
were based on the fourth examination cycle in 1997–2001,
when the men were approximately 77 years old (n¼838).

CONTACT Aleksandra Tonkonogi Aleksandra.tonkonogi@gmail.com Malma Backe 5K, 75647 Uppsala, Sweden
� 2016 The Author(s). Published by Informa UK Limited, trading as Taylor & Francis Group. This is an Open Access article distributed under the terms of the Creative Commons
Attribution License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly
cited.

UPSALA JOURNAL OF MEDICAL SCIENCES, 2016
VOL. 121, NO. 3, 174–178
http://dx.doi.org/10.1080/03009734.2016.1192704

http://ww.pubcare.uu.se/ULSAM
http://creativecommons.org/licenses/by/4.0/


Complete data for the subgroup of individuals with diabetes
were available for 91 participants. A written informed consent
was given by all participants, and the study protocol was
approved by the ethics committee of Uppsala University.

Medical information

Participants with diabetes at baseline were defined using the
following criteria: use of diabetes medication including oral
medication or insulin, or a fasting glucose �7.0 mmol/L.
Information about smoking habits and ongoing medications
was obtained using questionnaires. Height (cm), body (kg),
waist circumference (cm), BMI (kg/m2), hip circumference
(cm), and waist–hip ratio were measured. Blood pressure
(mmHg) was determined in the right arm with the subject in
supine position after 10 min of rest.

Clinical and biochemical analyses

All blood samples, venous, were drawn in the morning after an
overnight fast (14). Twenty-four-hour urinary samples were col-
lected. Urinary KIM-1 was analyzed (the cleaved extracellular part
which can be found in the urine) using a commercial ELISA kit
(DY1750 R&D Systems, Minneapolis, MN, USA). Urinary NGAL was
analyzed using an ELISA kit (DY1757, R&D Systems, Minneapolis,
MN, USA). Urine albumin was measured by nephelometry (urine
albumin, Dade Behring, Deerfield IL, USA), using a Behring BN
ProSpecV

R
analyzer (Dade Behring). Creatinine in the urine was

measured by means of a modified kinetic Jaffe reaction on an
Architect Ci8200V

R
analyzer (Abbott, Abbott Park, IL, USA), and

the aforementioned values were used to calculate urinary albu-
min–creatinine ratio (uACR). The analysis of urinary cystatin C
was carried out using a Mindray BS-380 (Shenzhen Mindray Bio-
medical Electronics, Shenzhen, China) with reagents from
Gentian (Moss, Norway). Serum cystatin C was analyzed with a
latex-enhanced reagent (N Latex Cystatin C, Dade Behring,
Deerfield, IL, USA) with a Behring BN ProSpec analyzer (Dade
Behring). HbA1c(%) was analyzed using a high-pressure liquid
chromatograph with a gradient system (BIO-RAD Laboratories).
HDL-cholesterol (mmol/L) was measured by separating the par-
ticles by precipitation with chloride and phosphotungstate. Total
cholesterol (mmol/L) in serum was analyzed using enzymatic
techniques, the IL Test Cholesterol Trinder’s Method 181618-10
in a Monarch apparatus (Instrumentation Laboratories, Lexington,
USA). Plasma glucose was measured using the glucose dehydro-
genase method (Gluc-DH, Merck, Darmstadt, Germany).
Estimated glomerular filtration rate (eGFR) was calculated using
serum cystatin C and by applying the formula y¼77.24x –
1.2623. For one of the Cox proportional hazard models albumin-
uria was dichotomized at 3 g/mmol creatinine.

All urinary biomarkers have been presented as a ratio to
urinary creatinine to compensate for varying urine concentra-
tions between the patients.

Outcome

Information about death due to cardiovascular disease was
obtained from the Swedish cause-of-death register and

defined as International Classification of Diseases (10th
Revision) codes I00–I99.

Statistical analysis

To investigate associations between cardiovascular mortality
and the novel kidney injury biomarkers multivariable Cox pro-
portional hazard models were used. Model A: crude; Model B:
adjusted for uACR; Model C: adjusted for eGFR; and Model D:
adjusted for uACR and eGFR. Additional Cox proportional haz-
ard analyses were carried out as secondary analyses, one
including uKIM-1/Cr and known cardiovascular risk factors
(systolic blood pressure, hypertension treatment, total choles-
terol, HDL, lipid-lowering medication, smoking, previous car-
diovascular event, HbA1c, diabetes medication, uACR, eGFR,
and atrial fibrillation). Moreover, Cox proportional hazard
models with all the three kidney injury biomarkers and uACR
and eGFR and a model with KIM-1/Cr as a dichotomous vari-
able, below or above 175 ng/mmol, microalbuminuria, and
chronic kidney disease CKD were carried out.

Results

Baseline characteristics can be seen in Table 1, which gives us
information about levels of the urinary biomarkers, smoking
habits, relevant medication, and much more.

During follow-up (median 8.3 years, interval 0.7–13.4 years)
33 participants died of cardiovascular causes (incidence rate
of 4.7 per 100 person years at risk). In Cox proportional haz-
ard analyses, adjusting for age and established kidney disease
biomarkers (eGFR and uACR), it was found that higher uKIM-
1/Cr was significantly associated with an increased risk for
cardiovascular mortality (Table 2).

Table 1. Baseline characteristics.

Variable Mean SD

A: Continuous variables
uKIM/Cr (ng/mmol) 121.4 10.2
uNGAL/Cr (ng/mmol) 2050.4 261.4
uCyst/Cr (ng/mmol) 14.0 0.003
Age (years) 77.8 0.17
Systolic blood pressure (mmHg) 152 4.43
Total cholesterol (mmol/L) 5.15 0.14
HDL(mmol/L) 1.16 0.04
BMI (kg/m2) 27.3 0.53
HbA1c (Mono S, %) 5.8 0.12
GFR-cyst (mL/min/1.73 m2) 73.5 2.5
uACR (mg/mmol) 1.5 0.33

n %
B: Categorical variables

Smoking 4 4
Hypertension treatment 61 67
Lipid-lowering treatment 23 25
Diabetes treatment 47 52
Previous CVD 7 8
Atrial fibrillation 12 14
Microalbuminuria 33 36
Chronic kidney disease 20 22

BMI: body mass index; GFR: glomerular filtration rate; HDL: high-density lipopro-
tein; previous CVD: previous cardiovascular disease events; uACR: urinary albu-
min–creatinine ratio; uCystC/Cr: urinary cystatin C–creatinine ratio; uKIM-1/Cr:
urinary kidney injury molecule-1–creatinine ratio; uNGAL/Cr: urinary neutrophil
gelatinase-associated lipocalin–creatinine ratio.

UPSALA JOURNAL OF MEDICAL SCIENCES 175



In secondary analyses, uKIM-1/Cr was still associated with
cardiovascular mortality when established cardiovascular risk
factors (systolic blood pressure, hypertension treatment, total
cholesterol, HDL cholesterol, lipid-lowering medication, smok-
ing, previous cardiovascular disease, HbA1c, diabetes medica-
tion) were added to Model D with adjustments for both uACR
and eGFR (HR per standard deviation (SD) increase of uKIM-1/
Cr 1.82, 95% CI 1.13–2.95, P¼0.01). Higher uCystC/Cr was
associated with an increased risk for CVD mortality in age-
adjusted models, but this association was attenuated and no
longer statistically significant after adjustment for both uACR
and eGFR (Table 2). Urinary NGAL/Cr was not associated with
increased CVD mortality in any model (Table 2). In a model
including all three urinary biomarkers as well as eGFR and
uACR, only uKIM-1/Cr and eGFR remained associated to car-
diovascular mortality (HR per SD increase of eGFR 0.58, 95%
CI 0.37–0.89, P¼0.01; and for uKIM-1/Cr 1.54, 95% CI
1.03–2.30, P¼0.03).

Discussion

In the present study, higher ratios of uKIM-1/Cr were associ-
ated with an increased risk of cardiovascular mortality even
after adjusting for established kidney disease markers and
cardiovascular risk factors. Neither urinary NGAL/Cr nor urin-
ary Cystatin C/Cr were independently associated with CVD
mortality risk in multivariable models. Our data provide add-
itional support for kidney tubular damage as an important
aspect of diabetic nephropathy that merits further
investigation.

There are a few previous community-based studies that
have reported an association between tubular damage bio-
markers and cardiovascular mortality (15–18). However, previ-
ous studies investigating the association between the urinary
kidney biomarkers and mortality risk in patients with diabetes
are scarce and inconsistent. In one study, KIM-1/Cr did not
provide additional prognostic value for 4-year mortality risk
after being adjusted for established CVD risk factors in 978
patients with type 2 diabetes (16). In contrast, a recent study
in Pima Indians with type 2 diabetes showed that higher urin-
ary KIM-1 was associated with increased long-term risk of
mortality but not end-stage renal disease (19). We are not
aware of any previous studies reporting the association
between urinary KIM-1 and cardiovascular mortality in
patients with diabetes. Perhaps differences between previous
studies and our study may be due to differences in outcome
(total versus CVD mortality), length of follow-up, sampling
procedure (spot sample versus 24-hour collection of urine) or

differences in age, ethnicity, and gender distribution of the
study samples.

Several mechanisms may explain the development of
tubular damage in diabetes. First, tubular hypertrophy has
been observed already after days of increased glucose levels
(2). Tubular cells are particularly vulnerable since their glucose
uptake is insulin-independent (2). Furthermore, hypertrophied
cells are maintained in the G1 phase of the cell cycle (20)
and are consequently more vulnerable to apoptotic stimuli.
Hyperglycemia also activates many growth factors. For
example, TGFb, which can be stimulated by advanced glyca-
tion end-products and angiotensin II (21,22), has been shown
to be involved in the development of tubular hypertrophy
(21). It has also been shown that higher urinary albumin may
directly damage the tubuli through induction of pro-inflam-
matory and pro-fibrotic changes (23), as well as apoptosis of
the tubular cells. Tubular hypoxia has also been shown to be
associated with nephropathy, and has been proposed to be a
fundamental factor underpinning development of chronic kid-
ney disease and end-stage renal disease (24). Yet, we cannot
say if hypoxia is mirrored by the KIM-1 levels in the individu-
als with diabetes in the present study.

The causal link between chronic tubular damage and the
development of cardiovascular disease is less clear. When kid-
ney function declines, calcium, potassium, urea, and various
harmful proteins accumulate; however, this may be more rele-
vant in later stages of kidney disease. Accumulation of harm-
ful substances may in turn lead to accelerated atherosclerosis
and hence CVD. Furthermore, tubular damage may result in
an increased reabsorption of sodium and water in the prox-
imal tubuli (2), which may lead to hypertension.

Neither urinary NGAL nor urinary cystatin C could be
linked to an increased risk of cardiovascular mortality. This
may partially be explained by the fact that NGAL expression
is not only limited to the kidneys as is the case with KIM-1.
NGAL is also a biomarker for inflammation. It is noteworthy
that cystatin C is taken up by the proximal tubule cells and
then degraded (7,8). Thus, findings of cystatin C in the urine
may mirror tubular dysfunction rather than specific tissue
damage.

The increased levels of urinary KIM-1, as seen in patients
with diabetes, may also be the result of reverse causation,
meaning that CVD itself results in higher levels of uKIM-1. It
has been shown that patients with prevalent congestive heart
failure have higher levels of KIM-1 compared to healthy con-
trols (25).

Diabetic nephropathy is a common and detrimental com-
plication of diabetes leading to increased morbidity and

Table 2. The association between urinary biomarkers and the risk for cardiovascular mortality: multivariate Cox proportional hazard regression.

Variable
Model A

Hazard ratio (95% CI)
Model B

Hazard ratio (95% CI)
Model C

Hazard ratio (95% CI)
Model D

Hazard ratio (95% CI)

uKIM-1/Cr 1.58 (1.13–2.22) 1.51 (1.04–2.19) 1.50 (1.08–2.10) 1.52 (1.03–2.24)
P 5 0.008 P 5 0.032 P 5 0.016 P 5 0.034

uNGAL/Cr 1.07 (0.78–1.48) 0.99 (0.71–1.39) 1.07 (0.76–1.48) 0.98 (0.68–1.43)
P¼0.66 P¼0.95 P¼0.71 P¼0.93

uCystC/Cr 1.26 (1.00–1.60) 1.16 (0.86–1.56) 1.09 (0.85–1.40) 1.02 (0.75–1.39)
P 5 0.049 P 5 0.033 P¼0.50 P¼0.89

P values: significant values in bold.
Model A: no adjustments; Model B: adjusted for uACR; Model C: adjusted for eGFR; Model D: adjusted for uACR and eGFR.

176 A. TONKONOGI ET AL.



mortality, mainly due to CVD. Therefore, it is of great clinical
importance to evaluate novel kidney injury biomarkers, which
may signal kidney damage at an earlier stage than microalbu-
minuria and reduced GFR. Interestingly, previous studies have
reported that elevated levels of KIM-1/Cr correlate with the
progression from normoalbuminuria to microalbuminuria (14)
and that urinary KIM-1/Cr is associated with insulin resistance
even prior to the development of diabetes (26), indicating
that urinary KIM-1/Cr could be an early marker for diabetic
nephropathy.

It is possible that KIM-1 could be used to monitor the pro-
gression or regression of nephropathy since levels of KIM-1 in
the urine decrease as a response to RAAS blockade (27).
However, it is not fully known if reduced levels of KIM-1 will
actually lead to decreased cardiovascular risk (15).
Importantly, the clinical relevance of KIM-1 screening in
patients with diabetes remains to be established, and further
large-scale studies are needed.

The main strength of our study is the longitudinal study
design with up to 13 years of follow-up. The main limitation is
the small study sample with few events during follow-up,
which led to limited statistical power to detect modest associa-
tions between kidney biomarkers and outcome. Yet, regardless
of the limited statistical power, uKIM-1/Cr predicted cardiovas-
cular mortality in all models. As the study participants were
elderly men, extrapolations of our findings to women and
other age groups and ethnicities have to be done cautiously.
We did not distinguish between type of diabetes; however,
diabetes type 2 is dominating among 77-year-old men in the
community, and we suggest that the results should be inter-
preted as if all individuals had type 2 diabetes.

In conclusion our data put forward urinary KIM-1/creatinine
as a promising biomarker for diabetic nephropathy and pro-
vide additional support for the importance of early tubular
damage as part of the underlying pathology of diabetic
nephropathy.

Acknowledgements

Aleksandra Tonkonogi and Axel C. Carlsson contributed equally to the
writing of this paper.

Disclosure statement

The authors report no conflicts of interest.

Funding information

This study was supported by The Swedish Research Council, Swedish
Heart-Lung foundation, the Marianne and Marcus Wallenberg Foundation,
Dalarna University and Uppsala University. The funding sources did not
play any role in the design and conduct of the study collection, manage-
ment, analysis, and interpretation of the data and preparation, review, or
approval of the manuscript. Dr €Arnl€ov is the guarantor of this work, had
full access to all the data, and takes full responsibility for the integrity of
data and the accuracy of data analysis.

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178 A. TONKONOGI ET AL.


	Associations between urinary kidney injury biomarkers and cardiovascular mortality risk in elderly men with diabetes
	Introduction
	Material and methods
	Medical information
	Clinical and biochemical analyses
	Outcome
	Statistical analysis

	Results
	Discussion
	Acknowledgements
	Disclosure statement
	Funding information
	References